Method for downloading data in a radio communications system

ABSTRACT

According to one aspect of the invention, in a radio communications system comprising at least one base station (BS 1 , BS 2 ) provided with means for transmitting data via a communication link (BCCH; V), wherein the data is divided into a plurality of data packets and being transmitted via the communication link to at least one receiving station (UE). To reduce power consumption it is proposed that the downloading of the data packets is halted if it is determined that a data packet has not been received or a corrupted data packet has been received by the receiving station, the missing or corrupted data packet is retransmitted via the same or a different communication link at a later time.

This invention describes the management of downloads in a radiocommunications system, especially a method for downloading software datain a cellular network with broadcast or dedicated bearer services.

Radio communications systems transmit data or information, especiallyspeech, picture information or other data via electro magnetic wavesbetween a base station and a user equipment (mobile or terminal). Wellknown communications systems are mobile telecommunications systems likeUMTS (Universal Mobile Telecommunication System) or wireless datanetworks like HiperLAN.

Within such communications systems data can be transmitted using on onehand one or more broadcasting channels for a point-to-multipointcommunication link or on the other hand one or more dedicated channelsof a point-to-point communication link. Information to be received by aplurality or all user equipments are transmitted by broadcasting thisinformation in a broadcast channel. Information, which will be receivedby only one or some special user equipments is transmitted viapoint-to-point links. Furthermore, paging information can be sent toseveral user equipments via point-to-point links.

Telecommunication systems like UMTS are divided into a number of cells.Each cell comprises a base station communicating with user equipmentswithin the cell via radio links. A radio link can be used for datatransmission in downlink from a base station to user equipments and inuplink for data transmission from user equipments to the base station.It is also known to employ sector antennas at the base station to covermultiple cell sectors.

In contrast to point-to-point channels broadcast channels are not powercontrolled and therefore increase the interference in adjacent cells andcell sectors. If broadcast is used in all cells, an additional decreaseof the overall cell capacity occurs due to intercell interference andcell coupling especially in CDMA (Code Division Multiplex Access)systems shich has a frequency reuse factor one. Cell coupling means thatan increase of transmission power in one cell leads to an increase intransmission power of neighbouring cells due to the need to maintain thesignal-to-interference relation for services. A specific downloadmanagement for all involved cells in a geographic area must be appliedwhen using cell broadcast in order to minimize the additionalinterference due to data download.

At present, the majority of wireless network user equipments work on abasis of software programs custom-designed for the appropriate operationof said equipments. These programs, however, frequently requiremodifications either in order to include new services that satisfy newuser requirements, or to update the existing services incorporating morerecent and improved versions of the existing software.

Due to rapid development of new program versions in the field ofcommunications technology, frequent updates or modifications arerequired, which should be fast, reliable and cheap.

In order to update software data it is known to handover the userequipment to an operative area that performs the downloading operationof the new software by means of physical and individual contacts in eachof them. This operation proves to be costly, inefficient as well asslow.

U.S. Pat. No. 5,689,825 discloses a method and a device for downloadingan updated software program to portable wireless communication devicewithout any intervention of the operator. A software program is updatedin a portable communications device by means of a software downloaderincorporated in the battery charger unit of said device. In this way,advantage is taken of the time dedicated to battery charging in order tocarry out the downloading of updated software into the memory of theportable communications device. According to said method, a serverreceives the updated software via a wireless network and stores it for alater transmission to the portable device for which the update isintended. Said server provides the data of the updated software to apublic land-based communications network which, internally, communicatesby a cable connection with the software downloader mentioned. Thesoftware downloader, after receiving a series of priority messages,starts to receive the updated of software in the form of blocks fromsaid public land-based communications network, stores that blocks,verifies if all the blocks have been received, and once reception hasbeen concluded, forwards the blocks to the portable device, therebycompleting the downloading process.

This method, however, is only applicable under conditions where use canbe made of a public land-based communications network. In addition, thedownloading of the software from the server to the portable destinationunit is done necessarily over cable. Furthermore, the method requiresthe use of a software downloading unit especially designed for thispurpose. In addition, access to the server is achieved by means ofmaking calls to said server, implying additional operating expenses.

EP 0 959 635 A1 discloses a method for connectionless downloading of asoftware program to a number of user equipments of a communicationsnetwork by broadcasting the software program in a downloading channel ofa base station. The program is thereby downloaded in fragmented form toa set of user equipments which ara grouped together according to theirsoftware version. The transmission takes place in repeated sequences.Each user equipment receives the repeated sequences of software programfragments, stores program fragments which it received error-free, andcontinues receiving repeated sequences until a complete version oferror-free received fragments has been stored. Thereafter, the userequipment sends a confirmation to the network, indicating that thedownload is completed. After a percentage of user equipments having sentconfirmations is equal to or greater than a threshold value, thedownloading process is stopped. User equipments which did not receivethe complete program, subsequently receive missing fragments by means ofconnection-oriented (point-to-point) procedures.

Problems in the aformentioned methods and systems arise when a userequipment leaves a cell in which the data is broadcasted before thecompletion of a download, as this situation is not covered. It istherefor one object of the present invention to provide a methodenabling the completion of a download even in case of for example ahandover.

The aforementioned problems are solved by features of the independentclaims. Preferred embodiments of the invention are addressed independent claims.

According to a first aspect of the invention, downloading of datapackets is halted if it is determined that either a data packet has notbeen received or that a corrupted data packet has been received by areceiving station. The missing or corrupted data packet is retransmittedvia the same or a different communication link at a later time.

This procedure is advantageous because the receiving station, e.g. auser equipment complying for example with a UMTS, WLAN or HiperLANstandard, need not receive and correct download data when there is toomuch interference on the channel used for transmission, thereby reducingthe power consumption of the station. As a side effect, because of theinterruption the overall interference in the system is reduced.

According to a second aspect of the invention, the downloading of thedata packets is halted if it is determined that a handover of thereceiving station is due, and resumed once the handover is concluded anda new communication link established.

An advantage of this method is that the download can be resumed after ahandover for example to another base station is concluded by using thenew established link. In contrast to methods known in the art it is notnecessary to subsequently receive data via a special interface. The newcommunication link used for receiving data packets can be a broadcastlink or a dedicated link.

According to a third aspect of the invention, the downloading of thedata packets in a broadcast channel is halted if it is determined thateither a data packet has not been received or that a corrupted datapacket has been received by the receiving station, and a dedicatedchannel is established for a retransmission of the missing or corrupteddata packet.

By using a dedicated-channel to conclude the download of data packets,the broadcast channel can be used for broadcasting data packetsbelonging to a different download or can just cease broadcasting therebyreducing interference. A further advantage of this aspect of theinvention is that a dedicated channel is generally used for apoint-to-point communication and therefore employs power controlmechanism or even transmits only in a certain direction in order tolimit interference.

The invention is now described with reference to the following drawings:

FIG. 1 shows an arrangement of communications system cells transmittingradio signals into sector cells in a circular cell grouping manner,

FIG. 2 shows a diagram illustrating system load via number of users whentransmitting signals via broadcasting channels and via dedicatedchannels, respectively.

FIG. 3 shows three user equipment modes and switching conditions betweenthese three basic modes.

FIG. 4 shows a frame structure and relationship between data channel andcontrol channel.

FIG. 5 shows a case in which the user equipment will leave downloadmode.

FIG. 6 shows a performance comparison between a packet indexing and nopacket indexing.

FIG. 7 shows session, packet and service relationships.

FIG. 8 shows a structure of a packet indexing scheme for labelingdownload sessions.

FIG. 9 shows protocol stacks in a radio network controller and in a userequipment.

FIG. 10 shows a timing table for jumping from download mode to aconnected mode.

FIG. 11 shows a worst case scenario of an alternative solution ofjudging the end of session.

In the following, the management and packet indexing scheme fordownloads are explained. This part is organized as follows: firstly,cell-grouping broadcast with traffic repetition is explained. Byintroducing the concept of download traffic classification, there isestablished the concept of download status and given the general idea toindicate the status of software downloads. Referring to the finisheddownload probability in a single cell, an interworking between broadcastand dedicated resources is established to finalize the downloads for allinvolved terminals. With proposing a protocol for handling fragmenteddownloads, new information elements are introduced to be exchanged bynetwork and terminals. Furthermore, a new terminal state (downloadstate) is introduced, which complements the well-known idle andconnected mode in e.g. 3GPP (3^(rd) Generation Partnership Project).Several alternatives for the protocol design and the needed informationelements are outlined.

FIG. 1 shows a simple arrangement of a radio communications systemcomprising a plurality of cells c1, c2, . . . , c7. Each cell c1, c2, .. . c7 comprises a base station BS1, BS2, . . . , BS7, in UMTS callednode B. The base stations BS1 can communicate with mobile terminals, inUMTS called user equipment UE, or other stationary stations via radiolinks V. There are different types of radio links. Broadcast channelsBCCH (Broadcast Control Channel) are used to provide a plurality of userequipments with the same data. Dedicated channels are used to build up acommunication between the base station BS1 and one or more selected userequipments UE. Data can be transmitted in downlink, i.e. from basestation BS1 to user equipment UE, or in uplink, i.e. from user equipmentUE to base station BS1. According to the preferred embodiment the cellsc1, c2, . . . , c7 each are sectorized to provide three cell sectors 1,2, 3.

An efficient cell download procedure can be organized in a circularmanner, shown in FIG. 1. The downloaded software is repeatedly broadcastin each cell. FIG. 1 is a snapshot illustrating the periodic repetition.In a first step, download data, especially download software data, aresent into subcell sector 1. In a next time period the same data are sentinto the subsector cells 2, and in a third time period the data are sentinto the third subsector cell of one, two or more of the cells c1, c2, .. . , c7.

In order to explain the approach more clearly, some terms are definedfirst. A service is a general term defined for the user equipmentUE-network communication. The network UMTS offers a service to the userequipment UE, e.g. a broadcast service, a dedicated service, etc. ASession is a type of data, e.g. one software module, one news package,etc., which is broadcasted in the network. For each download session thesession length can be defined. A packet is a fixed amount of datasegmented from the session. Each packet has its own index number in asession. Data or information has to be understood without limitation andcomprise every form of data and/or information which can be transmittedvia a radio link. Data are especially information data, load data andcontrol data/control signalling.

The download data can be classified into different classes according tothe user profile characteristics. So, download traffic classificationmeans to classify the software download traffic into a finite number ofclasses, e.g. upgraded software, driving news, stock market information,information from different service providers, etc. With the indicationof software download termination shown in the following, the concept ofsoftware download status is defined. The status of software downloadshows the current download traffic class and if the download process isfinished or in repetition/on-going status.

The reason to introduce a termination status is that a download sessioncannot always be repeated until a potential next session arrives. Due tonature of broadcast channels, a closed loop power control is notpossible. The interference from the broadcast channel will highlyinfluence the regular traffic. In case there is a certain small numberof download users for a session, this session is not necessary to betransmitted over the broadcast channel any more. Using a braodcastchannel creates much more interference than using only some dedicatedchannels being power controlled for software download.

FIG. 2 shows the design principle to choose a broadcast channel fordownloads. As the user number increases, shown in X-axis in FIG. 2, theload created by the download traffic using dedicated channels increasesexponentially. The load created by a broadcast channel is constant. Theintersection point between these two curves is the threshold of choosinga broadcast channel or to carry out the downloads with dedicatedchannels. Therefore, the grey shaded right side of the intersectionpoint is the area, where a broadcast channel should be selected for thedownload. The left side of the intersection point is the area, wherededicated channels should be used for downloads.

Therefore, a user equipment UE wishing to start a software downloaddecides to request software download via a dedicated channel in case ofhigh system load. On the other hand devices controlling base stationBS1, BS2, . . . , BS7 provide these base stations with software data tobe transmitted via broadcasting if system load or number of users is notbelow a threshold value which could be set depending on standard valuesor values considering regional conditions.

It is necessary or at least recommendable to introduce a third terminalstate “download state” for user equipment UE as shown below. We assumethe UMTS/FDD system (Universal Mobile TelecommunicationsSystems/Frequency Division Duplex) as one of the several systems ofinterest. An idle mode, a connected mode, and a download mode areaccessed by the terminal software.

As shown in FIG. 3, starting from idle mode the download mode,especially software download mode listening to the broadcast channel isestablished as one further mode for the user equipment UE. It can betriggered by a detected download paging information 1 (download statusinformation) carried by a control channel which will be introducedsubsequently. Once the download is finished, the terminal changes back 2to the idle mode. In the download mode, if a call is coming in,signalled by receiving radio resource control paging information 3 it isup to a Radio Resource Control (RRC) in the user equipment UE tointerrupt temporarily the current download process and to switch to theconnected mode 6. In case the connected mode is finished 4 and thedownload is still not finished, the UE should jump back to download mode5.

If the download process through a broadcast channel is terminatedaccording to principles shown in FIG. 2, a connected mode should beestablished 7 in order to finish the complete session as described laterin more detail.

A software download control channel (SCC) periodically broadcasts thecurrent status. If the current status indicates an on-going broadcast,the mobile user registered in this traffic class or willing to listen tothis class will decode the software download data channel (SDC) andstarts to download.

In addition, in order to have a higher probability to enhance thesoftware download, a time shift between this control channel and thebroadcast data channel should be also introduced.

In FIG. 4, two types of channels are introduced, the software downloadcontrol channel (SCC) and the software data channel (SDC). Via thecontrol channel there are transmitted pieces, i.e. packets, of softwaredownload control information which are repeated several times. Eachsoftware download control information comprises data regarding trafficclass/termination and a repetition indication field r, r=1, 2, . . . , Rwith R as the total repetition number. The data channel SDC starts laterthan the control channel SCC which indicates the current traffic classand repetition status. Data or data blocks transmitted via the datachannel comprises packets with packet indexing, load data and maybefurther information data.

The user equipment UE checks the control channel informationperiodically in order to save power. If it detects that the trafficclass carried by control channel SCC is identical to its registeredtraffic class, it starts to download data via the data channel SDC.

In case the downloading services should be terminated, the status ofdownloading termination should be shown in software download controlchannel SCC, and the software data channel SDC should be released. Thenetwork triggers a termination signal by setting r=0.

A field named repetition indication field r is introduced after atraffic type field tr. The repetition indication field r carries thecurrent repetition number r of the session. It indicates the detailedcurrent status of software download. It starts from the total repetitionnumber R decided by the download management in the network. When oneiteration of the download session is finished, the value r decreases byone. The user equipment UE reads the r-value and estimates the amount ofremaining packets which can be downloaded. The user equipment UEabandons the current reception, (1.:) if r equals to 1, (2.:) if still anumber of packets have not been correctly received for the currentsession, and (3.:) if the missing packet number is smaller than thecurrent packet index on the broadcast channel. The user equipment UEthen switches to idle mode or connected mode immediately to savebattery.

FIG. 5 illustrates this scenario. User equipment UE establishes thatonly a packet number 60 is missing or has been received corrupted andthat the value of the repetition indication field r is 1, i.e. it is thelast iteration step/last transmitting of this session by base station.If current packet number on broadcast channel is 100 then only packetshaving a packet number greater than 100 can be received. Therefore, userequipment UE could decide to abandon the download mode because there isno chance to receive missing or received corrupted packet with packetnumber 60.

Also, if the download was previously completed during an earlierrepetition, the reception of the broadcast should be stopped. Further,user equipment UE and/or a controlling device on side of the basestation BS1 like a radio network controller (RNC) can decide to stopsoftware download via dedicated channel and to switch to broadcastchannel, if number of users or system load exceed the said thresholdvalue, e.g. intersection point of FIG. 2.

Furthermore, user equipment UE can decide to stop software download fromthe broadcasting channel in the case that the user equipment UE movesfrom a first cell c1 to a second cell c2, thereby leaving the coveragearea of base station BS1 of first cell c1. After handover to basestation BS2 of second cell c2 user equipment UE can resume softwaredownload via radio link V2 to base station BS2 of the second cell c2.This radio link V2 can be either a broadcast channel or a dedicatedchannel. The same holds for a change of user equipment UE from radioreach of first subsector 1 of a cell c1 to a second subsector 2 of thesame cell c1.

In order to support the mechanism of software download repetition, anindexing scheme is introduced according to the preferred embodiment. Ano packet indexing case is identical to a single cell and no downloadrepetition scenario. In order to compare the software downloadperformance enhanced by the packet-indexing scheme, a simulationcomparing the performance without packet indexing and the case withpacket indexing has been arranged. On an upper bound it is assumed thatthe segmentation is sufficiently small to support seamless handover.However, performance is only one aspect of the system performance, sothe download process cannot be always repeated. The so called partyeffect well known from code division multiplex access (CDMA) behaviourcaused by a longer time download process and the real time requirementfor the waiting download traffic cannot allow the unlimited repetitionof the download. The following part illustrates that the success ratefor completed downloads is increased when repeating the broadcasts. Asalready mentioned this leads to fragmented downloads in terminals, andwith the procedures introduced in this application more finisheddownloads are accomplished, as can be seen from FIG. 6.

A frame structure containing the session and packet index is shown inFIG. 1 and FIG. 7. The software download control channel SDC carries thepacket indexes, session indexes, session status field, medium accesscontrol information and the download data, where the packet index andsession index are of major interest. Download data are the payloadcomprising software data to be downloaded as service information. Thepieces of medium access control (MAC) information are network controlinformation. The session status field s comprises a first value s=0representing an on-going session (OGS) or a second value s=1representing end of session EOS. Packet index n is running up to a finalnumber N.

In the download procedure, if the user stays in the cell c1 withoutleaving the serving cell in the download phase, it will finish thedownload successfully if we assume the link quality to be good enough.However, the investigation of finished download probability with respectto the data size, vehicular speed and broadcast channel capacity showsthat handovers to other channels or cells c2 during the download phasemust be taken into account and fragmentation will occur. The fragmenteddownloads in terminals can be finalized by introducing a packet indexand other information elements e.g. the repetition indication field rcombined with a suitable protocol.

The user equipment UE keeps receiving the download session whilechecking the received packet index n and reassembles the order ofpackets with respect to the received indexes. If the number of receivedpackets is the same as the number indicated in the final packet labeledby the EOS signal in the session status field (s=1), the whole sequenceof the packets in the current session is successfully downloaded. InFIG. 7, the on-going session index OGS (s=0) shows the current receivedpacket is on-going session broadcast; the EOS signal shows the end ofsession.

The packet index n is a number composed of hierarchical two-level codes,a local packet index and a global session number as depicted in FIG. 8.

The on-going session OGS and end of session EOS signal helps the userequipment UE to judge whether it has successfully downloaded the currentsession. The session status fields need only one bit. Anotheralternative way of indicating the end of the session is to broadcast thetotal number N of packets for the current download session in the lowdata rate control channel, i.e. in the software control channel SCC.

The number as shown in FIG. 8 can be seen as the absolute packet index ncomprising the packet index of the current session and the session indexof a global session numbering. The reason to have an absolute packetindex n is to avoid overlaps if two packets with the same relativepacket number but belonging to different sessions are received. Theprotocol stacks in the Radio Network Controller (RNC) and the userequipment UE must support this approach. A new logical channel calledsoftware data channel (SDC) should be established in the radio accessnetwork in order to handle the download traffic for addressing manyusers. For instance, a third common physical channel could beestablished in UMTS/FDD to carry this logical channel.

As shown in FIG. 9, the Radio network controller (RNC) and optional thebase station BSi/node B has the responsibility to organize the labelingfor download traffic. With respect to the physical layer radio networkcontroller RNC and/or base station (node B) starts with application ofsession segmentation. Thereafter, a session indexing and mapping tological channel follows. After this session segmentation into packets,e.g. into transport blocks, as provided. After this mapping to transportchannels with packet indexing comprising a local field and a globalfield is provided to transport data via the physical layer.

The user equipment UE reassembles the received packets into a completesession. User equipment UE provides a mapping to transport channels withpacket indexing comprising the local field and the global field withrespect to the physical layer. Thereafter, a packets reassembling intosession follows. This block in FIG. 9 is an important point of oneaspect of the invention according to a preferred embodiment, whichenables the user equipment UE to complete the broadcast information.Thereafter, a mapping to logical channel has to follow. After this anapplication of session reassembling has to be provided.

In case the download phase by means of repetition is finished and theuser equipment UE has not completed the download, he should apply for adedicated radio resource. The download session can be received duringdifferent cell affiliations, i.e., due to handover. During the lifetimeof a broadcast session, fragments of the session are received.

A simplified mobile switching center (MSC) chart between the userequipment UE and network in case the mode jumps from download mode tothe connected mode is shown in FIG. 10.

Starting from download mode the user equipment UE detects an unfinisheddownload after download in the broadcast channel has been terminated.Therefore, user equipment UE sends the missing packet index n comprisingpacket index number of the current session and the session number ofglobal session numbering to the radio network controller RNC of thecommunicating network (e.g. UTRAN: UMTS Terrestrial Radio AccessNetwork). Network devices like the radio network controller establish aradio resource control (RRC) connection, e.g. dedicated link between abase station BS1 and user equipment UE. Thereafter, user equipment UEswitches to connected mode in order to receive missing software data viadata transmission via the dedicated channel.

Alternative 1:

The terminologies introduced previously is only to build up the conceptof software download using a packet indexing scheme. The similarfunctionality can be realized by upgrading available control channels,e.g. forward access channels (FACH) indicated by the broadcast controlchannel (BCCH). There are many alternative ways to fulfill therequirement of software download. E.g. the user equipment UE candetermine that the session is finished by observing the event when therepetition field r is decreased by one. In this case, the end of sessionEOS and on-going session OGS signalling are not needed. However, theprobability of successful judgment of finished downloads is lower.

The following FIG. 11 shows the worst case scenario when an erroroccurs. The user equipment UE judges whether or not a session in thecurrent iteration is finished by comparing Whether or not r_(old) isequal to r_(new)+1. If not, other functions will be executed. If yes,the user equipment compares the received number of packets to the packetnumber in the previous packet. If for example packet number 100 ismissing or received corrupted, the comparing step of the protocol willnot work. As a consequence, the total number of packets in this sessionwill be wrongly determined as 99, not 100.

The most important information should be carried out by the airinterface. The packet-indexing scheme can be realized alternatively.There are still number of alternative means to inform the user equipmentUE how many packets the session has, e.g.:

Alternative 2:

The total packet number N can be broadcasted by the periodic softwaredownload control channel SCC. In this case the session status fields arenot needed. However, software download channel SDC cannot workindependently from the software download control channel SCC.

Alternative 3:

The total packet number N can be carried in each transport block in thesoftware download control channel SDC. In this case it looses spectrumefficiency, if maximum number N of repetitions is large.

Features of the invention, which might present independent inventiveaspects, are discussed in the following:

-   a. A first inventive aspect is the introduction of download session    repetition using common channels, e.g. broadcast. The packet    indexing scheme enhances its performance. It mainly resolves the    unfinished download problem due to handover and radio bearer service    selection.    -   In case the user equipment UE changes its affiliation from a        base station BS1 in a first cell c1 to a base station BS2 of        another cell c2 where both cells c1 and c2 are repeatedly        broadcasting the download stream, the user equipment UE can        selectively receive the missing part of a session.    -   In case the bearer service has been changed for the user        equipment UE, e.g. due to interference reason, in case when the        download channel is changed from broadcast channel to dedicated        channel, the user equipment UE still can apply for the missing        packets to complete the unfinished download. A table of missing        packet is sent to the network after the broadcast session.

Furthermore, in a multi-download service type scenario, i.e., whendifferent cells are broadcasting different sessions, user equipment UEcan select the right session thanks to the session differentiationenhanced by session index.

One realization of combining the session status field and packet indexis introduced. It brings the advantage of increasing probability ofcorrectly decoding the whole packet number for a download session, asshown in FIG. 11.

-   b. According to a second inventive aspect there is introduced a    frame structure for the software download channels, i.e. software    download control channel (SCC) in parallel with data channel (SDC)    as shown in FIG. 4, where the session repetition indication field r    carries the current repetition number inexplicitly showing how many    repetitions are left. Based on this value, the user equipment UE    abandons the software download mode, if there is no chance to finish    the download via common channels.-   c. according to a third inventive aspect a new download terminal    state (mode) is introduced whereby the following advantages are    evident:    -   Interworking between control information and the data channel        broadcast with a time shift (delay time) to increase the        finished download probability.    -   Terminal based decision to abandon the download state, if        already successfully completed the download or if no further        chance exist to complete by broadcast session.-   d. A further important feature is based on c. As shown in FIG. 10,    in case the user equipment UE switches from download mode to    connected mode during its download process, it should submit the    missing packet numbers and related session number in the reverse    link to the network.-   e. Since the packet indexing approach can be independently    implemented in different cells, it can be also independently    implemented with respect to the cell grouping approach. The idea if    introducing the control information telling the current download    status in order to page the software download user equipment UE is    not only limited in the UMTS/FDD system. In any system where    especially the push service is employed it can be implemented.

1-16. (canceled)
 17. A method for downloading data in a radiocommunications system, the system including at least one base stationwith means for transmitting data via a communication link, the methodwhich comprises: dividing data into a plurality of data packets;transmitting the data packets via the communication link to at least onereceiving station; halting a download of the data packets upondetermining that a data packet has not been received or that a corrupteddata packet has been received by the receiving station; andretransmitting the non-received or corrupted data packet via the same ora different communication link at a later time.
 18. The method accordingto claim 17, which comprises transmitting the data packets in abroadcast channel to the receiving station, and establishing a dedicatedchannel for retransmitting the non-received or corrupted data packet.19. The method according to claim 17, which comprises repeatedlyretransmitting the non-received or corrupted data packet via the newcommunication link.
 20. The method according to claim 17, whichcomprises marking each of a plurality of data packets assigned to asession with a session index.
 21. The method according to claim 20,which comprises assigning a packet index to each of the data packets ofa session, the packet index including the session index and anindividual packet number.
 22. The method according to claim 17, whichcomprises selectively halting and continuing the download of the datapackets depending on a determined system load or a number of receivingstations communicating with the base station.
 23. The method accordingto claim 22, which comprises using a broadcast link to continue thedownload of data packets if the system load or the number of receivingstations exceed a predetermined threshold, whereas, if the system loador the number of receiving stations lies below the predeterminedthreshold, using at least one dedicated channel.
 24. The methodaccording to claim 17, which comprises signaling at least one of an endof session command and a number of further retransmissions of thesessions to the receiving station.
 25. The method according to claim 17,wherein the data is software data for adapting or modifying software ofthe receiving station.
 26. The method according to claim 17, whichcomprises using a broadcast channel with a reduced transmission powerfor transmitting the data.
 27. The method according to claim 17, whichcomprises changing an affiliation of a user equipment, forming thereceiving station, from a first base station to a second base stationand selectively receiving a missing part of a session from the basestations repeatedly broadcasting a download stream.
 28. The methodaccording to claim 17, which comprises, in case a bearer service ischanged or the download channel is changed from a broadcast channel to adedicated channel, requesting the non-received or corrupted data packetwith the receiving station by signaling a table of missing packets tothe base station.
 29. The method according to claim 17, which comprises,in a multi-download-service scenario with multiple cells eachbroadcasting a different session, selecting with the receiving station asession by way of a session index.
 30. A method for downloading data ina radio communications system, the system including at least one basestation with means for transmitting data via a communication link, themethod which comprises: dividing data into a plurality of data packets;transmitting the data packets via the communication link to at least onereceiving station; halting a download of the data packets upondetermining that a handover of the receiving station is due; andsubsequently resuming the download of the data packets via a newcommunication link after a conclusion of the handover.
 31. The methodaccording to claim 30, which comprises marking each of a plurality ofdata packets assigned to a session with a session index.
 32. The methodaccording to claim 31, which comprises assigning a packet index to eachof the data packets of a session, the packet index including the sessionindex and an individual packet number.
 33. The method according to claim30, which comprises selectively halting and continuing the download ofthe data packets depending on a determined system load or a number ofreceiving stations communicating with the base station.
 34. The methodaccording to claim 33, which comprises using a broadcast link tocontinue the download of data packets if the system load or the numberof receiving stations exceed a predetermined threshold, whereas, if thesystem load or the number of receiving stations lies below thepredetermined threshold, using at least one dedicated channel.
 35. Themethod according to claim 30, which comprises signaling at least one ofan end of session command and a number of further retransmissions of thesessions to the receiving station.
 36. The method according to claim 30,wherein the data is software data for adapting or modifying software ofthe receiving station.
 37. The method according to claim 30, whichcomprises using a broadcast channel with a reduced transmission powerfor transmitting the data.
 38. The method according to claim 30, whichcomprises changing an affiliation of a user equipment, forming thereceiving station, from a first base station to a second base stationand selectively receiving a missing part of a session from the basestations repeatedly broadcasting a download stream.
 39. The methodaccording to claim 30, which comprises, in case a bearer service ischanged or the download channel is changed from a broadcast channel to adedicated channel, requesting the non-received or corrupted data packetwith the receiving station by signaling a table of missing packets tothe base station.
 40. The method according to claim 30, which comprises,in a multi-download-service scenario with multiple cells eachbroadcasting a different session, selecting with the receiving station asession by way of a session index.
 41. A radio communication system,comprising at least one base station and at least one receiving stationeach having means for carrying out the method according to claim
 30. 42.A station of a radio communication system, comprising means for carryingout the method according to claim
 30. 43. A radio communication system,comprising at least one base station and at least one receiving stationeach having means for carrying out the method according to claim
 17. 44.A station of a radio communication system, comprising means for carryingout the method according to claim 30.